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First published online 2 December 2004
doi: 10.1242/dev.01563

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Mouse Disp1 is required in sonic hedgehog-expressing cells for paracrine activity of the cholesterol-modified ligand

Hua Tian^1,*, Juhee Jeong^2,*, Brian D. Harfe³, Clifford J. Tabin⁴ and Andrew P. McMahon^5,

¹ One DNA Way, Genentech Incorporated, South San Francisco, CA 94080, USA
² 1550 Fourth Street, Room 282, UCSF Mission Bay Campus, San Francisco, CA 94158, USA
³ University of Florida College of Medicine, Department of Molecular Genetics and Microbiology, 1600 SW Archer Road, Gainesville, FL 32610-0266, USA
⁴ Department of Genetics, Harvard Medical School, NRB room 360, 77 Avenue Louis Pasteur, Boston, MA 02115, USA
⁵ Department of Molecular and Cellular Biology, The Biolabs, Harvard University, 16 Divinity Avenue, Cambridge, MA 02138, USA

Author for correspondence (e-mail: mcmahon{at}mcb.harvard.edu)

Accepted 4 November 2004

	SUMMARY

TOP SUMMARY Introduction Materials and methods Results Discussion REFERENCES

 
Previous studies have demonstrated that Disp1 function is essential for Shh and Ihh signaling in the mouse, and Disp1 gene dose regulates the level of Shh signaling activity in vivo. To determine whether Disp1 activity is required in Shh-producing cells for paracrine signaling in Shh target fields, we used a Shh^GFP-Cre (here shortened to Shh^Cre) knock-in allele and a Disp1 conditional allele to knock down Disp1 activity specifically within Shh-producing cells. The resulting facial and neural tube phenotypes support the conclusion that the primary and probably exclusive role for Disp1 is within hedgehog protein-producing cells. Furthermore, using an allele that produces N-Shh (a noncholesterol modified form of the Shh protein), we demonstrate that N-Shh is sufficient to rescue most of the early embryonic lethal defects in a Disp1-null mutant background. Thus, Disp1 activity is only required for paracrine hedgehog protein signaling by the cholesterol modified form of Shh (N-Shhp), the normal product generated by auto-processing of a Shh precursor protein. In both respects, Disp function is conserved from Drosophila to mice.

Key words: Dispatched1, Shh, Cholesterol, Paracrine, Autocrine

	Introduction

TOP SUMMARY Introduction Materials and methods Results Discussion REFERENCES

 
The hedgehog (Hh) family of secreted proteins control tissue growth and patterning in many key developmental processes in both vertebrates and invertebrates. In mammals, there are three hedgehog genes (Echelard et al., 1993): sonic hedgehog (Shh), Indian hedgehog (Ihh) and desert hedgehog (Dhh). All three can act as potent mitogens, survival factors and inducers of distinct cell types in a dose-dependent manner (reviewed by McMahon et al., 2003). Shh is essential for early patterning of the ventral CNS, and somite and anterior-posterior organization of the limb. Shh also plays a redundant role with Ihh in establishment of left-right asymmetry (Zhang et al., 2001). Later in development, Shh is involved in the growth and morphogenesis of several organs, including hair, tooth, lung, gut and kidney, whereas Ihh coordinates growth and differentiation of the endochondral skeleton, Dhh is required for development of the peripheral nerve, testicular organization and spermatogenesis.

As extracellular signals, Hh proteins are synthesized in discrete subsets of cells in many organs and act in short and long-range signaling processes. The best characterized mammalian Hh-target field is the developing ventral neural tube, where progenitors differentiate into several different cell types in response to a morphogen gradient of Shh, issuing from two point sources: the notochord and floorplate (Briscoe and Ericson, 1999; Briscoe and Ericson, 2001; Jessell, 2000; McMahon et al., 2003). The notochord is a ventral rod of mesoderm that underlies the neural tube while the floorplate is a population of support cells at the ventral midline of the neural tube that is induced by notochordal Shh. Distinct ventral neural progenitors are induced at specific positions with respect to the source, and apparent concentration, of Hh ligand.

All Hh proteins are synthesized as full-length precursors that undergo an autocatalytic cleavage reaction. This removes the C-terminal catalytic domain and attaches a cholesterol molecule to the C terminus of the N-terminal signaling fragment (N-Shhp; `p' stands for `processed' in the N-Shh signaling moiety) (Porter et al., 1996a). The hydrophobic cholesterol moiety is thought to bind Hh to the cell membrane. The hydrophobicity of the Hh molecule is further increased by the addition of a palmitoyl group to a conserved cysteine residue that is exposed at the N terminus after signal peptide cleavage (Pepinsky et al., 1998). These modifications regulate Hh activity, oligomerization, range of action, potency and might in many cases, shape a signaling gradient (Burke et al., 1999; Chamoun et al., 2001; Chen et al., 2004; Chen and Struhl, 1996; Kohtz et al., 2001; Lee et al., 2001; Lewis et al., 2001; Zeng et al., 2001). The requirement for such modifications may depend on the context in which Hh proteins act (Chen and Struhl, 1996; Lewis et al., 2001). As cholesterol modification is unique to Hh-ligands, the role of cholesterol has attracted considerable attention. Forms of Hh ligand have been engineered that lack the autocatalytic cleavage site and C-terminal cleavage domain, and therefore are not cholesterol-modified [Hh-N in Drosophila (Chen and Struhl, 1996) and NShh in mammals (Lewis et al., 2001)]. In both instances, palmitoylation appears to be largely independent of cholesterol addition (Chen et al., 2004; Gallet et al., 2003).

Despite dual lipid modifications that normally retain protein on the cell membrane, Drosophila Hh and mouse Shh and Ihh protein can be detected at significant distances from their expression domains (Chen and Struhl, 1996; Gallet et al., 2003; Gritli-Linde et al., 2001; Lewis et al., 2001; Porter et al., 1996a). This long-distance action is an active process involving a transmembrane protein Dispatched (Disp). Disp was first identified in Drosophila studies, where its activity is required specifically within Hh-producing cells for movement of cholesterol modified ligand into Hh target fields (Burke et al., 1999). By contrast, Hh-N signaling is Disp independent (Burke et al., 1999).

The mouse has two Disp homologs, Disp1 and Disp2, but only Disp1 is able to rescue a Drosophila disp mutant phenotype (Ma et al., 2002). Genetic studies in zebrafish suggest that Disp2 is not involved in Hh signaling (Nakano et al., 2004), and mouse studies support this view (H.T. and A.P.M., unpublished). Three mutant alleles of mouse Disp1 have been described: Disp1⁸, Disp1^C829F and Disp1² (Caspary et al., 2002; Kawakami et al., 2002; Ma et al., 2002; Tian et al., 2004). Analysis of these alleles lead to similar general conclusion, that Disp1 is involved in Hh signaling during early embryonic development. Among these mutant alleles, the Disp1⁸ deletion allele (Kawakami et al., 2002; Ma et al., 2002) and Disp1^C829F missense allele (Caspary et al., 2002) are likely to represent null alleles of Disp1. Homozygous Disp1⁸ and Disp1^C829F mutants do not survive beyond E9.5, and exhibit gross morphological features that are similar to Smoothened (Smo) mutants in which all Hh signaling activity is abolished (Zhang et al., 2001). In Disp1^C829F/C829F and Disp1^8/8 embryos, Hh signaling is retained but only in midline cells of the notochord that both produce Shh and respond to Shh signals (Ma et al., 2002). Disp1², by contrast, encodes a hypomorphic allele (Tian et al., 2004). Homozygous Disp1² mutants die at birth with facial midline patterning defects, characteristic of attenuated Shh signaling (Wallis and Muenke, 1999). This hypomorphic allele has permitted us to demonstrate the genetic interaction of Disp1 with specific components of the Hh signaling pathway. By combining a Disp1² hypomorphic allele with Disp1^C829F, Shh^null and patched 1 (Ptch1^null) alleles, we created a set of graded facial midline and neural tube phenotypes demonstrating that Disp1 gene dose regulates the level of Shh signaling activity in vivo. Furthermore, rescue of the Disp1^2/2 mutant upon removing one copy of Ptch1 suggested that Disp1 functions exclusively in the Hh pathway (Tian et al., 2004).

Although these phenotypic analyses demonstrated a conserved requirement for Disp1 in the Hh signaling pathway and highlighted the importance of Disp1 dose for normal levels of Shh signaling, they did not address the specific cellular or molecular limits to Disp1 action in mammalian Hh signaling. To determine whether Disp1 activity is required in Shh-producing cells or in paracrine signaling in the target field, we used a Shh^Cre knock-in allele to remove Disp1 exon 2 specifically from Shh-producing cells. Our results indicate that Disp1 activity in these cells is essential for Hh signaling to the target field. Furthermore, using an allele that produces N-Shh, we demonstrate that Disp1 activity is required only for the paracrine action of the cholesterol modified form of Shh.

	Materials and methods

TOP SUMMARY Introduction Materials and methods Results Discussion REFERENCES

 
Mice
Disp1^C829F/+ mice were kindly provided by Kathryn Anderson (Caspary et al., 2002). The Sox2Cre and Shhⁿ (Shh^-) alleles have been described previously (Hayashi et al., 2002; St-Jacques et al., 1998). The construction of Shh^GFP-Cre (here shortened to Shh^Cre) is described by Harfe et al. (Harfe et al., 2004). N-Shh^C alleles will be reported in detail elsewhere (J.J. and A.P.M., unpublished). In short, Cre-mediated recombination leads to the generation of an allele functionally identical to the N-Shh allele reported by Lewis et al. (Lewis et al., 2001). Mutants were studied on a mixed genetic background, principally 129SV, C57BL6/J and SW.

Generation of Disp1^2C and Disp1² alleles
To remove exon 2 of Disp1, a targeting vector was engineered in which exon 2 was flanked by loxP sites. Exon 2 encodes the amino terminal cytoplasmic domain and first transmembrane domain of Disp1 (Tian et al., 2004). After homologous recombination at the Disp1 locus in AV3 ES cells, a heterozygous ES cell line was injected into blastocysts of the C57BL6/J strain to generate chimeras. These were bred with Swiss Webster mice to obtain Disp1^2C/+ offspring. Chimeric males were also bred with ß-actin-Cre females, Cre activity in the preimplantation embryo allow the recovery of Disp1^2/+ heterozygous offspring.

RNA in situ hybridization
Embryos were fixed in 4% paraformaldehyde at 4°C overnight. Whole-mount and section in situ hybridization using digoxigenin-labeled RNA probes was performed as described previously (Schaeren-Wiemers and Gerfin-Moser, 1993; Wilkinson, 1992).

Immunofluorescence
Immunofluorescence on embryonic sections was performed as described for sections (Yamada et al., 1991). Antibodies and dilutions were as follows: rabbit Foxa2, 1:8000 (Ruiz i Altaba et al., 1995); Nkx6.1, 1:3000 (Cai et al., 2000); Nkx2.2, 1:4000 (Briscoe et al., 1999); Olig2, 1:5000 (Takebayashi et al., 2000); mouse Nkx2.2, 1:50 (Ericson et al., 1997a); Pax6, 1:20 (Ericson et al., 1997b); Pax7, 1:20 (Ericson et al., 1996); and MNR2, 1:20 (DHSB).

Skeletal preparations
For skeletal preparations, 18.5 dpc embryos were processed as described previously (Karp et al., 2000).

	Results

TOP SUMMARY Introduction Materials and methods Results Discussion REFERENCES

 
Generation of a tissue specific knockout of Disp1 exon 2 in the Shh-expressing cells
To remove Disp1 activity specifically from the Shh expression domain using the Cre/loxP system, we first generated a Disp1-conditional allele (Disp1^2C) by flanking the first coding exon with DNA recognition sites (loxP) for Cre recombinase (Cre) (see Tian et al., 2004). Mice homozygous for this allele (Disp1^2C/2C) were viable and fertile with no discernible phenotype, indicating that Disp1^2C has a wild-type function (data not shown). Conversion of Disp1^2C into a Disp1² allele in the presence of Cre recombinase is highly efficient, as demonstrated by our previous study in which a ubiquitous Disp1² allele was generated by crossing a ß-actin Cre transgene onto a Disp1^2C/+ background (Tian et al., 2004).

To knock down Disp1 activity specifically within Shh-producing cells, we used a Cre knock-in allele in which sequence encoding a GFP-Cre fusion protein was inserted into the Shh locus (Shh^GFP-Cre, herein Shh^Cre) (Harfe et al., 2004). This allele no longer expresses a normal Shh transcript, and is a null allele for Shh activity. When combined with a Cre reporter line R26R (Soriano, 1999), Shh^Cre gave rise to lacZ expression that was almost identical to Shh mRNA distribution at E10.5 (Fig. 1A,B), indicating that the GFP-Cre fusion protein is functionally active within all Shh expression domains. To further confirm the functional specificity of GFPCre fusion protein, Shh^Cre was crossed with a Shh conditional allele (Shh^2C) (Lewis et al., 2001) to remove Shh in the Shh-producing cell.

View larger version (57K): [in this window] [in a new window]   Fig. 1. ShhCre was effective in removing Shh activity from all Shh-producing cells. (A,B) The distribution of Shh mRNA (A) and lacZ activated in compound heterozygous for the ShhCre and R26R reporter allele (B) are very similar. External morphology of E10.5 embryos (C-E). Shh-null embryo (D) is almost identical to ShhCre/C (E). In Shh-/- mutants (G,J,M,P), the floorplate (G) and distinct ventral progenitors [Olig2+ (J), Nkx6.1+ (M) and Nkx2.2+ (P) cells] are absent. Furthermore, Pax7 (M) and Pax6 (P), negative targets of Hh signaling, move ventrally to occupy the entire ventral neural tube. In the ShhCre/C mutant, one or two Nkx6.1+ cells remain (arrow in N) in the ventral neural tube, which is indicative of some low level signaling prior to Cre activity.

Appropriate crosses were set up to generate mice that were either Disp1^2/2C, Shh^Cre/+ or Disp1^C829F/2C, Shh^Cre/+. In both cases, pups died within 1 day of birth. In the former, Shh^Cre activity should generate Shh-expressing cells that are homozygous for the Disp1^2/2 allele. In the latter, the only Disp1 activity comes from a single Disp1² hypomorphic allele. In both examples, Disp1 activity is decreased on a background where Shh dose is lowered by the presence of the Shh^Cre null allele. Ordinarily, reducing Shh levels by removing one allele of Shh produces no discernible phenotype (Chiang et al., 1996; St-Jacques et al., 1998) but reduction of Shh dose enhances the neural phenotype in Disp1 hypomorphic combinations (Tian et al., 2004) Importantly, as the production of Cre recombinase is linked to Shh expression, some level of Shh signaling must take place prior to Cre-mediated modification of Disp1 alleles. This is evident in Shh^Cre/C embryos where a few Nkx6.1-producing cells are observed (Fig. 1N), while no Nkx6.1 are produced in Shh^-/- embryos (Fig. 1L,M).

In both genotypes (Disp1^2/2C, Shh^Cre/+ or Disp1^C829F/2C, Shh^Cre/+), pups displayed facial midline defects similar to Disp1 hypomorphic mutants (Disp1^2/2, Shh^+/- and Disp1^C829F/2, Shh^+/-), in which Disp1 exon 2 was deleted in the entire embryo, the severity of the phenotype increased as Disp1 activity decreased (Fig. 2A-E). Importantly, no phenotype was observed in Disp1^2/2C, Shh^+/- embryos (data not shown). The midline facial defects were clearly visible at E10.5 by comparing the ventral disposition of the medial and lateral nasal process and proximal mandibular and maxillary arches that are highlighted by the expression of Fgf8 (Fig. 2F-J). In Disp1^2/2C, Shh^Cre/+ embryos, the two nasal pits were positioned closer to the midline, indicating a loss of facial midline structure. A more severe phenotype was seen in Disp1^C829F/2C, Shh^Cre/+ embryos as the two nasal pits start to fuse where Shh-dependent medial nasal cells were also affected (Fig. 2J). The severity of the midline loss in conditional mutants was comparable with Disp1 hypomorphic mutants Disp1^2/2, Shh^+/- and Disp1^C829F/2; Shh^+/- (compare Fig. 2G and I with 2H and J). Skeleton preparations of newborn pups revealed that the premaxilla was missing from Disp1^2/2C, Shh^Cre/+ and Disp1^C829F/2C, Shh^Cre/+ mutant embryos, just as in Disp1^C829F/2, Shh^+/- and Disp1^2/2, Shh^+/- embryos (Fig. 2K-O). Although the parietal bone was also lost in Disp1^C829F/2, Shh^+/- embryos, we only observed a delay in ossification of parietal bones in Disp1^C829F/2C, Shh^Cre/+ mutant (compare Fig. 2N,O). As expected from the analysis of Disp1^2/2, Shh^+/- and Disp1^2/C829F, Shh^+/- mutants, expression of Ptch1, one of the principle transcriptional targets of Hh signaling, was greatly downregulated in the frontal nasal process (FNP) of the conditional mutants at E9.5 (Fig. 2P-T, arrows). This confirms that the loss of midline structures of the frontal nasal process in the conditional mutants Disp1^2/2C, Shh^Cre/+ and Disp1^C829F/2C, Shh^Cre/+ was due to the attenuation of Shh signaling in this region. Furthermore, Shh expression within the ventral forebrain, which is itself a target of a mesendodermal derived Shh signal, was lost in all allelic combinations (Fig. 2U-Y). This most probably explains the initial defect in FNP development in the Disp1 mutant background.

View larger version (97K): [in this window] [in a new window]   Fig. 2. Attenuating Disp1 activity specifically in Shh-producing cell phenocopies Disp1 hypomorphic mutants. (A-E) External facial morphology of E18.5 embryos. Disp1 conditional mutants (C,E) display a spectrum of midline facial defects that result in a pointed face and nose that are similar but slightly milder than Disp12/2, Shh+/- and Disp1C829F/2, Shh+/- embryos (B,D). (F-J) Fgf8 in situ to demarcate the epithelium of the nasal pit. Two nasal pits, which are positioned well apart in wild type (F), are brought closer to the midline in Disp12/2, Shh+/- and Disp12/2C, ShhCre/+ (G,H), and are fused at the midline in Disp12/C829F, Shh+/- (I). The fusion of the nasal pits occurs at a more medial position in Disp1C829F/2C, ShhCre/+ embryos (J). (K-O) Alcian Blue (non-mineralized cartilage) and Alizarin Red (mineralized cartilage and bone) stained skeletons of E18.5 embryos. The premaxilla and upper incisor are missing from all mutants. The premaxilla, upper incisor and parietal bone are missing from Disp12/C829F, Shh+/- (N) but not in the conditional mutant Disp1C829F/2C, ShhCre/+ (O). Midline facial defects are due to attenuation of Shh induction and signaling in the ventral forebrain. (P-Y) Whole-mount in situ of Ptch1 (P-T) and Shh (U-Y) at E9.5 show an absence of Ptch1 upregulation in the frontal nasal process of the mutants and a failure of Shh induction in the ventral forebrain.

Spinal cord patterning defects in Disp1^2/2C, Shh^Cre/+ and Disp1^C829F/2C, Shh^Cre/+ mutant

Disp1^2/2, Shh^+/-

Disp1^2/2, Shh^+/-

Disp1^2/2, Shh^+/-

Disp1^2/2, Shh^+/-

Disp1^2/2, Shh^+/-

View larger version (137K): [in this window] [in a new window]   Fig. 3. Attenuation of Disp1 activity in the Shh-producing notochord leads to a similar disruption of ventral neural tube patterning, as observed in Disp1 hypomorphic mutants. Sections through the neural tube of wild-type (A-E), Disp1 hypomorphic mutants (Disp12/2, Shh+/-) (F-J), Disp1C829F/2, Shh+/- (P-T), and Disp1 conditional mutants [Disp12/2C, ShhCre (K-O) and Disp1C829F/2C, ShhCre/+ (U-Y)]. In Disp12/2, Shh+/- mutant (F-J): the floorplate is absent (F); Nkx2.2+ and Olig2+ cells are greatly reduced in number (G); Nkx2.2+ cells occupy the ventral midline (G); Nkx6.1+-positive cells are also affected (H); and the dorsal marker Pax7 is restricted to the dorsal domain (H). The conditional mutant Disp12/2C, ShhCre/+ maintains the early floorplate marker Foxa2 but no Shh expression is observed in the floorplate (K). Nkx2.2+ and Olig2+ cells are reduced in number to about 50% of the wild-type control levels and Nkx2.2+ cells occupy the ventral midline (L). In Disp12/C829F, Shh+/- mutant (P-T), ventral progenitor cell numbers are further reduced compared with Disp12/2, Shh+/-. No Nkx2.2+ cells are present (S) and the Pax7 and Pax6 domains move ventrally (R,S). Nkx2.2+ cells are still present in Disp1C829F/2C, ShhCre/+ mutants (X).

2/2C

Disp1^2/2C, Shh^Cre/+

Disp1^2/2C, Shh^Cre/+

Disp1^2/2C, Shh^Cre/+

Disp1^2/2

Disp1^2/2C, Shh^Cre/+

Disp1^2/2, Shh^+/-

Disp1^2/2

Disp1^2C/C829F

Disp1²

Disp1^2/C829F, Shh^+/-

Signaling by N-Shh is independent of Disp1 activity
Next, we addressed the specific requirement for Disp1 for cholesterol modified Shh ligand. We have previously reported on an N-Shh allele generated by inserting a stop-codon into the endogenous Shh gene at the position where normal cleavage and cholesterol addition occurs (Lewis et al., 2001). The protein produced is identical to that of the normal Shh signal and is expected to undergo N-terminal palmitoylation (Chen et al., 2004). Unfortunately, this allele is dominant lethal, highlighting the importance of cholesterol modification to normal Hh regulation (Lewis et al., 2001). To overcome this dominant lethality and to enable us to address N-Shh activity in a Disp1^C829F/C829F mutant background that lacks all Disp1 activity, we created a conditional N-Shh (N-Shh^C) allele (J.J. and A.P.M., unpublished). Mice heterozygous for this allele are viable and fertile permitting genetic intercrosses with the Disp1^C829F allele. Cre-mediated recombination leads to exclusive production of N-Shh from the endogenous Shh locus, an outcome that is essentially identical to the original non-conditional N-Shh allele. To initiate recombination throughout the embryo, we used a Sox2Cre transgene to induce recombination in the entire embryo (Hayashi et al., 2002). As the resulting N-Shh allele is under identical cis-regulatory control to the wild-type Shh allele, N-Shh expression was restricted to Shh-expressing cells (data not shown). Unlike Disp1^C829F/C829F mutants, which do not survive beyond 9.5 dpc and show gross defects in neural, somite, cardiac, vascular, facial and limb development (Fig. 4A,B), Disp1^C829F/C829F, NShh^C/Shhⁿ, Sox2Cre embryos were alive at E10.5 but die at or around birth. Morphologically, these embryos were indistinguishable from the N-Shh^C/Shhⁿ, Sox2Cre mutants (Fig. 4C,D), which also employ N-Shh as the only available Shh ligand. At this stage, both Disp1^C829F/C829F, N-Shh^C/Shhⁿ, Sox2Cre and N-Shh^C/Shhⁿ, Sox2Cre mutant embryos are very similar to the wild type, except for midline defects in the frontal nasal process. Thus, Disp1 does not appear to be required for N-Shh activity.

View larger version (32K): [in this window] [in a new window]   Fig. 4. N-Shh rescues Disp1C829F/C829F mutant at E10.5. Gross morphology of the (A) wild-type, (B) Disp1C829F/C829F, (C) N-ShhC/Shhn; Sox2Cre, (D) N-ShhC/Shhn; Sox2Cre; Disp1C829F/C829F embryos at E10.5.

Disp1^8/8

View larger version (61K): [in this window] [in a new window]   Fig. 5. Shh signaling is restored in the limb bud of N-Shh rescued Disp1-null mutants. Whole-mount in situ hybridizations with antisense riboprobes for Shh (A-C) and Ptch1 (D-F) in limb buds of wild-type (A,D), N-ShhC/Shhn; Sox2Cre (B,E) and N-ShhC/Shhn; Sox2Cre; Disp1C829F/C829F (C,F) embryos at 10.5 dpc as indicated. Shh gene expression is restricted to the posterior mesenchyme in the wild type (A). N-Shhp from this domain diffuses anteriorly, which then leads to a graded Ptch1 expression across the entire posterior half of the limb field (D). The expression of N-Shh is induced in the posterior mesenchyme in N-Shh mutant (B). Ptch1 is reduced and restricted to the posterior mesenchyme (E). High levels of Ptch1 expression are restricted to Shh-producing cells and to cells immediately anterior to this domain. No gradient of expression is apparent across the AP axis. Similar levels of Shh and Ptch1 expression are observed in limb buds of N-Shh rescued Disp1 mutant embryos (C,F).

Disp1^2/C829F

View larger version (56K): [in this window] [in a new window]   Fig. 6. Ventral spinal cord patterning defects in Disp mutants are rescued by N-Shh. Floorplate and ventral progenitors see in wild type (A,G) are not induced in Disp1C829F/C829F mutants (B,H). Similarly, floorplate and pV3 progenitors (Nkx2.2+) cells are not induced in Disp1C829F/2, Shh+/- mutant (E,K). N-Shh signaling induces floorplate and ventral neural progenitors in the absence of Disp1 activity in Disp1C829F/C829F; NShhC/Shhn; Sox2Cre mutant (D,J) and in Disp1C829F/2, N-ShhC/Shhn, Sox2Cre embryos (F,L), similar to the pattern observed in N-ShhC/Shhn, Sox2Cre (C,I) embryos. Shh signaling is restored in the ventral neural tube as shown by Ptch1 expression (M-R). Although N-Shh is not detected by immunofluorescence in the floorplate of N-ShhC/Shhn, Sox2Cre embryos (C,D,F, compare with A), Shh is expressed at the ventral midline, indicating that floorplate induction has occurred (S-X) in the floorplate of N-ShhC/Shhn, Sox2Cre embryos independent of Disp1 activity.

Disp1^2/C829F

Disp1^2/C829F

	Discussion

TOP SUMMARY Introduction Materials and methods Results Discussion REFERENCES

 
Disp1 functions in production of a paracrine Shh signal
We have taken advantage of distinct alleles of Disp1 to examine the requirement for Disp1 in Hh signaling in the mouse. Previous reports have demonstrated that Disp1 function is essential for Shh and Ihh signaling (Caspary et al., 2002; Kawakami et al., 2002; Ma et al., 2002). Furthermore, a comparative analysis of autocrine and paracrine functions suggested that Disp1 is not required for autocrine signaling where Hh-producing cells are themselves targets of Hh signaling (e.g. Shh in the notochord), but Disp1 is essential for paracrine signaling to responsive cell populations adjacent to the sources of ligand (Caspary et al., 2002; Ma et al., 2002). These data suggest that Disp1 may function in release of active ligand from Hh-producing cells to adjacent target populations as is the case for Disp in Drosophila (Burke et al., 1999).

In this study we have used a variety of genetic strategies to examine Disp1 action. In the previous studies, the precise cellular requirements for Disp1 were unclear. Here, we specifically attenuated Disp1 activity in Shh-expressing cells; strikingly, the phenotypes closely resemble those observed when Disp1 activity is reduced in the entire embryo (Tian et al., 2004). That these phenotypes are not identical is most likely a technical limitation of our approach. In this, we used a conditional hypomorphic allele of Disp1 where essential sequence encoded within exon 2 was flanked by loxP sites and combined this allele with a Shh^Cre allele to `knock down' Disp1 levels exclusively within Shh-expressing cells. In this genotype, Cre-dependent recombination at the Disp1^2C locus can occur only after Shh transcription is initiated; hence, it is likely some Shh signaling occurs while there is a sufficient level of Disp1 to lead to normal signaling (embryos heterozygous for Disp1^null/+ alleles are phenotypically wild-type). Alternatively, as this approach is only expected to modify Ihh signaling where Shh and Ihh expression overlap, wild-type Ihh activity from non-Shh expressing cells may contribute to the weaker phenotype in the conditional allele. The presence of a few Nkx6.1⁺ cells in Shh^Cre/C embryos is consistent with the former explanation.

With these provisos in mind, it is striking that the phenotypes of attenuated Disp1 activity in the Shh expression domain and in the whole embryo are so similar. Clearly, most if not all, paracrine Shh signaling within the face, neural tube and limb is dependent on Disp1 function in the ligand-producing cell, supporting a model in which Disp1 acts in signal production and not target cell response. How Disp1 acts at the molecular and cellular level is not clear. Studies in Drosophila report the accumulation of Hh ligand in Disp1 mutant cells in the posterior compartment of the imaginal disc (Burke et al., 1999), suggesting that Disp1 may regulate the release of bulk ligand from Hh-producing cells. Further work implicates Disp in apical trafficking (Gallet et al., 2003) within Hh-producing epithelia, suggesting that the defective release and ligand accumulation in Hh-producing cells may be secondary to altered membrane trafficking. However, we failed to observe any obvious accumulation of Shh in Shh-producing cells in Disp1-null mutant embryos (data now shown). We also failed to observe any differences in the release of bulk Shh protein into the medium when Shh was expressed in Disp1^C829F/C829F or wild-type fibroblasts (Tian et al., 2004). Whether this represents a difference between polarized epithelia and fibroblasts is unclear. Interestingly, reports of a highly active multimeric complex of lipid modified Hh ligands (Zeng et al., 2001) raises the possibility that Disp1 may function not in general release of ligand, but rather in the formation and/or release of an active fraction that is composed of Hh oligomers. Clearly, there is enhanced bioactivity in media conditioned by Shh-expressing fibroblast when Disp1 is active in these cells (Ma et al., 2002).

Disp1 is only required for paracrine signaling activity of cholesterol modified forms of Shh
Cholesterol-modification of Hh ligands plays a key role in Hh signaling. In Drosophila, removal of cholesterol from Hh increases the range of ligand action, at least in part through a disruption of normal Ptch-dependent feedback control that normally sequesters ligand (Chen and Struhl, 1996). Whereas Ptch1 mediated sequestration of N-Shh is also defective in the mouse, cholesterol modification of N-Shhp is essential for long-range action in the limb (Lewis et al., 2001). Thus, although there appears to be species or context-dependent differences in the role of cholesterol in Hh signaling, in both flies and mice cholesterol-modification of Hh ligands is essential for normal signaling within a multicellular target field. In Drosophila, Disp is required only for signaling by cholesterol-modified forms of Hh (Burke et al., 1999). Our work in the mouse indicates a similar requirement for Disp1. Whereas, Disp1-null embryos arrest at E9.5 dpc with multiple defects, including an absence of ventral cell identities in the neural tube, expression of a single allele of N-Shh is sufficient to rescue many of these deficiencies. In the resulting neural tube, all Shh-dependent ventral cell identities are represented leading to a phenotype identical to that of N-Shh/Shhⁿ embryos on a wild-type Disp1 background.

Interestingly, when we examined N-Shh localization in the floorplate and notochord in N-Shh/Shhⁿ embryos, we were unable to detect any immunoreactivity (in contrast to embryos carrying a single wild-type alleles of Shh). Thus, N-Shh appears to be rapidly lost from Shh secreting cells, whereas NShhp is retained and accumulates within the cell, a finding supported by earlier cell culture analyses (Bumcrot et al., 1995; Porter et al., 1996b). These results highlight the challenge faced in moving a cholesterol-tethered Shh ligand from the initial Shh-producing cell into the target field and the vital role Disp1 plays in this process. Recent studies have demonstrated that N-Shh fails to generate a soluble multimeric protein complex, lending further support to a link between Disp1 and oligomeric forms of Shh ligand (Chen et al., 2004; Zeng et al., 2001). That Disp1 shares a sterol sensing domain with Ptch1 and several proteins that regulate cholesterol biosynthesis or trafficking (Carstea et al., 1997; Hua et al., 1996) suggests cholesterol sensing by Disp1 plays some role in regulation of N-Shhp export.

Finally, given that Hh ligands undergo a second lipid modification, an N-terminal palmitoylation, how does this relate to Disp1 function? Early studies first noted that when NShh was highly expressed in tissue cultures, a reduced fraction of secreted ligand was palmitoylated compared with cells expressing wild-type N-Shhp (Pepinsky et al., 1998). However, more recent studies suggest that palmitoylation is largely independent of cholesterol addition (Chen et al., 2004; Gallet et al., 2003). Furthermore, loss of palmitoylation, but not cholesterol, results in a dramatic reduction in Hh and Shh activity (Chamoun et al., 2001; Chen et al., 2004; Lee et al., 2001). However, N-Shh retains biological activity in the neural tube (data herein) and limb (Lewis et al., 2001). Thus, it is likely that the N-Shh allele we have generated gives rise to an N-terminal palmitoylated ligand. If so, this lipid modification does not appear to be sufficient for retention of Shh ligand in Shh-producing cells from our data. Although both nonpalmitoylated and non-cholesterol tethered Shh (N-Shh) ligands both fail to form oligomers (Chen et al., 2004), N-Shh retains bioactivity while bioactivity is lost in non-palmitoylated Shh. One possible explanation for these results is that the ready secretion of N-Shh ligand may counteract the failure of oligomerization in paracrine signaling in the embryo. By contrast, continued membrane retention and an absence of oligomerization of non-palmitoylated cholesterol-modified Shh ligand may lead to an absence of sufficient active signal within the target field to mediate any paracrine signaling in the mouse embryo.

	ACKNOWLEDGMENTS

 
We thank Drs Kathryn Anderson and Tamara Caspary for allowing us to use Disp1^C829F/+ before the publication of this allele and for helpful discussion; Jill McMahon for ES cell injection; and Diane Faria for histology. For the gift of antibodies, we thank Jen Jensen (Nkx6.1), Ariel Ruiz i Altaba (Foxa2), Hirohide Takebayashi (Olig2) and Tom Jessell (Nkx2.2). B.H. was supported by a NRSA postdoctoral grant from NIH (NRSA AR08642). Work in C.J.T.'s laboratory was supported by a grant from the NIH (HD32443) and work in A.P.M.'s laboratory was supported by a grant from the NIH (NS33642).

	Footnotes

 
^* These authors contributed equally to this work

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